Cost effective cartridge for a plasma arc torch

ABSTRACT

A cartridge for an air-cooled plasma arc torch is provided. The cartridge includes a swirl ring having a molded thermoplastic elongated body with a distal end, a proximal end, and a hollow portion configured to receive an electrode. The swirl ring also has a plurality of gas flow openings defined by the distal end of the elongated body and configured to impart a swirling motion to a plasma gas flow for the plasma arc torch. The swirl ring further includes a nozzle retention feature on a surface of the elongated body at the distal end for retaining a nozzle to the elongated body. The cartridge further includes a cap affixed to the proximal end of the elongated body of the swirl ring for substantially closing the proximal end of the elongated body.

CROSS REFERENCE TO RELATED APPLICATION

This application is a continuation application of Ser. No. 14/824,946,filed on Aug. 12, 2015 and entitled “Cost Effective Cartridge for aPlasma Arc Torch,” which claims the benefit of and priority to U.S.Provisional Patent Application No. 62/036,393, filed Aug. 12, 2014. Theentire content of both applications is owned by the assignee of theinstant application and incorporated herein by reference in itsentirety.

TECHNICAL FIELD

The present invention generally relates to consumables for a plasma arctorch, and more particularly, to one or more replaceable, low-costcartridges of a plasma arc torch having multiple integrated components.

BACKGROUND

Thermal processing torches, such as plasma arc torches, are widely usedfor high temperature processing (e.g., heating, cutting, gouging andmarking) of materials. A plasma arc torch generally includes a torchbody, an electrode mounted within the torch body, an emissive insertdisposed within a bore of the electrode, a nozzle with a central exitorifice mounted within the torch body, a shield, electrical connections,passages for cooling, passages for arc control fluids (e.g., plasma gas)and a power supply. A swirl ring can be used to control fluid flowpatterns in the plasma chamber formed between the electrode and thenozzle. In some torches, a retaining cap is used to maintain the nozzleand/or swirl ring in the plasma arc torch. In operation, the torchproduces a plasma arc, which is a constricted jet of an ionized gas withhigh temperature and sufficient momentum to assist with removal ofmolten metal. Gases used in the torch can be non-reactive (e.g., argonor nitrogen), or reactive (e.g., oxygen or air).

One method for producing a plasma arc in a plasma arc torch is thecontact start method. The contact start method involves establishingphysical contact and electrical communication between the electrode andthe nozzle to create a current path between them. The electrode and thenozzle can cooperate to create a plasma chamber within the torch body.An electrical current is provided to the electrode and the nozzle, and agas is introduced to the plasma chamber. Gas pressure builds up untilthe pressure is sufficient to separate the electrode and the nozzle. Theseparation causes an arc to be formed between the electrode and thenozzle in the plasma chamber. The arc ionizes the introduced gas toproduce a plasma jet that can be transferred to the workpiece formaterial processing. In some applications, the power supply is adaptedto provide a first electrical current known as a pilot current duringgeneration of the arc and a second current known as a transferred arccurrent when the plasma jet has been transferred to the workpiece.

Various configurations are possible for generating the arc. For example,the electrode can move within the torch body away from the stationarynozzle. Such a configuration is referred to as the “blow-back” contactstart method because the gas pressure causes the electrode to move awayfrom the workpiece. A problem with such systems relates to precisealignment of the nozzle and electrode consumables, which significantlyimpacts life expectancy of the consumables and material processing/cutquality. In another configuration, the nozzle can move away from therelatively stationary electrode. Such a configuration is referred to asthe “blow-forward” contact start method because the gas pressure causesthe nozzle to move toward the workpiece.

Existing plasma cutting systems include a large array of consumablesavailable for use with different currents and/or operating modes. Thelarge number of consumable options requires large part counts andinventories for users, and can confuse users and increase thepossibility of installing incorrect consumables. The large number ofconsumable options can also cause lengthy torch setup time(s) and makeit difficult to transition among cutting processes that requiredifferent arrangements of consumables in the torch, arrangement andinstallation of which is often performed in the field. For example,before a cutting operation, selecting and installing the correct set ofconsumables for a particular cutting task can be burdensome andtime-consuming. Furthermore, selection, assembly, and installation ofthese components in the field can cause alignment issues orcompatibility issues when old components are used with new components.During torch operation, existing consumables can experience performanceissues such as failing to maintain proper consumable alignment andspacing. Furthermore, current consumables include substantial amounts ofexpensive materials (e.g., Vespel™) and often require a relativelycomplex manufacturing process, which lead to significant manufacturingcosts and inhibit their widespread commercialization, production andadoption. What is needed is a new and improved consumable platform thatdecreases manufacturing costs and time, decreases part count, increasessystem performance (e.g., component alignment, cut quality, consumablelife, variability/versatility, etc.), and eases installation and use ofconsumables by end users.

SUMMARY

The present invention provides one or more cost effective cartridgedesigns for a plasma arc torch, such as for a manually-operated,air-cooled plasma arc torch. Generally, because a cartridge includes asuite of two or more consumable components, it provides ease of use andshortens the time for installation into a plasma arc torch in comparisonto installing each consumable component individually. In addition, theuse of a cartridge in a torch improves component alignment and cutconsistency. However, manufacturing and material costs can prohibit thewidespread commercialization and production of cartridges. The presentinvention solves this problem by providing one or more cost effectivecartridge designs that facilitate cartridge commercialization andproduction and improve their installation.

The invention, in one aspect, features a cartridge for an air-cooledplasma arc torch. The cartridge comprises a swirl ring and a cap. Theswirl ring includes a molded thermoplastic elongated body having asubstantially hollow portion, the molded thermoplastic elongated bodyhaving a distal end and a proximal end and configured to receive anelectrode within the hollow portion. The swirl ring also includes aplurality of gas flow openings defined by the distal end of theelongated body and configured to impart a swirling motion to a plasmagas flow for the plasma arc torch. The swirl ring further includes anozzle retention feature on a surface of the elongated body at thedistal end for retaining a nozzle to the elongated body. The cap isaffixed to the proximal end of the elongated body of the swirl ring. Thecap substantially encloses the proximal end of the elongated body.

In some embodiments, the cap is formed of an electrically conductivematerial. The cap can be configured to retain the electrode within thecartridge and pass an electrical current to the electrode. The cap cancomprise a biasing surface for physically contacting a resilient elementthat biases against a proximal end of the electrode. Additionally, thecap can comprise a substantially hollow body configured to retain theresilient element between the biasing surface and the proximal end ofthe electrode.

In some embodiments, the body of the cap has a substantially uniformthickness. In some embodiments, the cap includes at least one vent hole.

In some embodiments, the cap comprises a contact surface forfacilitating electrical contact with a corresponding contact surface ofthe electrode when the plasma arc torch is operated in a transferred arcmode. The contact surface of the cap is characterized by the absence ofcontact with the corresponding contact surface of the electrode duringinitiation of a pilot arc. The contact surface can be configured tophysically contact the corresponding contact surface of the electrodewhen the torch is operated in the transferred arc mode.

In some embodiments, the plurality of gas flow openings of the swirlring include slots defined by a plurality of extensions disposed aboutthe distal end of the elongated body of the swirl ring, each slotsituated between a pair of the extensions.

In some embodiments, the nozzle retention feature includes a groovelocated on an external surface of the extensions. Retention of thenozzle to the swirl ring can be via one of snap fit, threading orcrimping. In some embodiments, engagement between the cap and the swirlring is by one of crimping, snap fit, or threading.

In some embodiments, the elongated body of the swirl ring is molded froma thermoplastic material comprising a polymer formed of ether and ketonemolecules. The thermoplastic material can have one or more propertiescomprising (i) a glass transition temperature (Tg) of greater than about320 Fahrenheit (F), (ii) a coefficient of linear thermal expansion(CLTE) of less than about 22 micro-inch/inch-Fahrenheit (micro.in/in.F)below Tg, (iii) a CLTE of less than about 55 micro.in/in.F above Tg,(iv) a melting point of greater than about 720 Fahrenheit, and (v) adielectric strength of greater than about 480 kilo-volt/inch.

In some embodiments, the ratio of an axial length (L) of each gas flowopening to an average radius (R) between the radius of the electrode andthe radius of an inner wall of the swirl ring is less than about 0.5. Insome embodiments, the plurality of gas flow openings are disposed in asingle layer about the distal end of the elongated body, each gas flowopening having an offset of about 0.040 inches between an opening in aninner wall of the swirl ring and an opening on an outer wall of theswirl ring.

In another aspect, a molded swirl ring for an air-cooled plasma arctorch is provided. The molded swirl ring comprises a moldedthermoplastic elongated body comprising a substantially hollow portion.The molded thermoplastic elongated body has a distal end and a proximalend and configured to receive an electrode within the hollow portion.The molded swirl ring also includes a plurality of molded gas flowopenings each extending from an interior surface to an exterior surfaceof the elongated body. The molded gas flow openings are disposed aboutthe distal end of the elongated body and configured to impart a swirl toa plasma gas flow of the plasma arc torch. The molded swirl ring furtherincludes a nozzle retention surface on the body for retaining a nozzleat the distal end of the elongated body.

In some embodiments, the plurality of gas flow openings include slotsdefined by a plurality of extensions disposed about the distal end ofthe elongated body, each slot situated between a pair of the extensions.The distal end of the elongated body of the swirl ring and the nozzlecan cooperatively define the plurality of gas flow openings.

In some embodiments, the nozzle retention surface includes a nozzleretention feature located on an external surface of the extensions. Thenozzle retention feature can comprise a groove configured to receive aportion of the nozzle via crimping. In some embodiments, the nozzleretention surface comprises a sloped surface configured to receive aportion of the nozzle via crimping.

In some embodiments, the swirl ring is configured to engage the nozzlevia one of snap fit or threading. In some embodiments, the swirl ring isconfigured to engage the nozzle via crimping.

In some embodiments, the elongated body is molded from a thermoplasticmaterial comprising a polymer formed of ether and ketone molecules. Thethermoplastic material can further comprise one or more additives.

In another aspect, an assembly for an air-cooled plasma arc torch isprovided. The assembly comprises an electrode, a swirl ring molded froma thermoplastic material, a nozzle, and a cap. The swirl ring comprisesa nozzle retention surface at a distal end and a cap retention elementat a proximal end. The nozzle is fixedly secured to the distal end ofthe swirl ring via the nozzle retention surface, where the nozzleincludes an exit orifice at a distal end of the nozzle. The cap isfixedly secured to the proximal end of the swirl ring via the capretention element. The cap is configured to enclose the swirl ring atthe proximal end. The securement of the swirl ring, the nozzle and thecap creates a chamber in which the electrode is permanently disposed andaligned relative to the nozzle.

In some embodiments, the nozzle retention surface comprises a slopedsurface and the nozzle is secured to the distal end of the swirl ring bycrimping at least a portion of the nozzle against the sloped surface.The crimping of the nozzle to the nozzle retention can establish (1) aradial centering of the nozzle exit orifice within the chamber withrespect to a distal end of the electrode to within 0.005 inches, and (2)a longitudinal positioning of the electrode within the chamber betweenthe distal end of the electrode and the nozzle exit orifice during atransferred arc operation of the assembly to within 0.030 to 0.060inches.

In some embodiments, the cap retention element comprises a grooveconfigured to secure the swirl ring by at least one of crimping,threading, or snap fit. The securement of the cap to the swirl ring viathe cap retention element can establish a longitudinal positioning ofthe electrode within the chamber between a distal end of the electrodeand the nozzle exit orifice during a transferred arc operation of theassembly to within 0.030 to 0.060 inches.

In some embodiments, the assembly further comprises a resilient elementbetween a biasing surface of the cap and the electrode, the resilientelement physically contacting the electrode and imparting a separationforce upon the electrode. The resilient element can pass substantiallyall of a pilot arc current to the electrode when the plasma arc torch isoperated in a pilot arc mode. The cap can comprise a hollow body formaintaining the resilient element substantially therein. In someembodiments, the resilient element comprises at least one of a spring orwire.

In some embodiments, the assembly further comprises an o-ring configuredto substantially surround the proximal end of the swirl ring to seal theswirl ring against a body of the plasma arc torch.

In another aspect, a cap is provided for a contact start plasma arctorch configured for electrical communication with an electrode. The capcomprises a substantially hollow body, formed from an electricallyconductive material, configured to receive a resilient element. Thehollow body has a substantially uniform thickness. The cap also includesa biasing surface at a proximal end of the cap for physically contactingthe resilient element. The cap further includes an interior contactsurface at the distal end for physically contacting, during atransferred arc mode of the plasma arc torch, a corresponding surface atthe proximal end of the electrode. The contact surface is characterizedby an absence of contact with the corresponding surface of the electrodeduring a pilot arc mode of the plasma arc torch.

In some embodiments, the contact surface is configured to pass at leasta portion of a transferred arc current from the power supply to theelectrode during the transferred arc mode. Additionally, the resilientelement can be configured to pass substantially all of a pilot arccurrent from the power supply to the electrode during the pilot arcmode.

In some embodiments, the cap further includes a retention element forconnection to a swirl ring via one of crimping, snap fit or threading.In some embodiments, the cap further includes at least one vent hole. Insome embodiments, the cap further comprises a circular tunnel portionthat includes the biasing surface and is configured to house at least aportion of the resilient element. In some embodiments, the cap furthercomprises a depressed center extending away from the proximal end thatincludes the contact surface.

In some embodiments, the cap is formed via a stamping process.

In another aspect, a method for aligning a plurality of components in acartridge is provided. The method includes molding a thermoplasticmaterial to form a swirl ring comprising a distal end, a proximal endand a hollow body. The method also includes disposing an electrodeinside of the hollow body of the swirl ring and retaining the electrodeto the cartridge by fixedly securing the nozzle to the distal end of theswirl ring. The method further includes longitudinally aligning theelectrode relative to the nozzle by fixedly securing an end cap to theproximal end of the swirl ring, thereby establishing the longitudinalalignment during a transferred arc operation of the cartridge when a gasflow is used to bias the electrode into contact with the end cap.

In some embodiments, the method further comprises forming the end capvia a stamping process. In some embodiments, the method furthercomprises radially aligning the electrode by restraining a radial motionof the electrode within the hollow body of the swirl ring.

In some embodiments, the longitudinal alignment comprises restraining alongitudinal motion of the electrode to within a blow-back distancedefined by a distal end of the electrode and an exit orifice of thenozzle during the transferred arc operation.

In some embodiments, fixed securing the nozzle to the distal end of theswirl ring comprises crimping a portion of the nozzle into a retentionsurface on the distal end of the swirl ring.

BRIEF DESCRIPTION OF THE DRAWINGS

The advantages of the invention described above, together with furtheradvantages, may be better understood by referring to the followingdescription taken in conjunction with the accompanying drawings. Thedrawings are not necessarily to scale, emphasis instead generally beingplaced upon illustrating the principles of the invention.

FIG. 1 is a cross-sectional view of an exemplary cartridge for a plasmaarc torch, according to an illustrative embodiment of the invention.

FIG. 2 is an isometric view of the electrode of the cartridge of FIG. 1, according to an illustrative embodiment of the invention.

FIG. 3 is an isometric view of the nozzle of the cartridge of FIG. 1 ,according to an illustrative embodiment of the invention.

FIGS. 4 a and 4 b are isometric and profile views of the swirl ring ofthe cartridge of FIG. 1 , respectively, according to an illustrativeembodiment of the invention.

FIGS. 5 a and 5 b are isometric and sectional views of another swirlring design compatible with the cartridge of FIG. 1 , respectively,according to an illustrative embodiment of the invention.

FIG. 6 is a sectional view of the swirl ring of the cartridge of FIG. 1with the electrode aligned within the swirl ring and illustrating anexemplary gas flow opening.

FIGS. 7 a and 7 b are isometric and sectional views of the end cap ofthe cartridge of FIG. 1 , respectively, according to an illustrativeembodiment of the invention.

FIG. 8 is an exemplary shield design compatible with the cartridge ofFIG. 1 , according to an illustrative embodiment of the invention.

FIG. 9 is an exploded view of the cartridge of FIG. 1 , according to anillustrative embodiment of the invention.

DETAILED DESCRIPTION

FIG. 1 is a cross-sectional view of an exemplary cartridge 100 for aplasma arc torch, according to an illustrative embodiment of theinvention. As shown, the cartridge 100 includes an end cap 106, a swirlring 102, an electrode 104, and a nozzle 108 oriented substantiallysymmetrically about the longitudinal axis A. The cartridge 100 canadditionally include a resilient element 122 and/or a sealing device150. The cartridge 100 can use a blow-back contact starting mechanismfor contact starting the plasma arc torch upon assembly into the torch.Specifically, the electrode 104 can be a spring-forward electrode, whichmeans that the resilient element 122 (e.g., a spring) can exert aseparating force on the proximal end 124 of the electrode 104 to biasthe electrode 104 away from the end cap 106 and toward the nozzle 108.

FIG. 2 is an isometric view of the electrode 104, according to anillustrative embodiment of the invention. As shown, the electrode 104includes a set of spiral-shaped fins 114 for directing a gas flow andfacilitating cooling of the cartridge 100. An emissive insert 142 (i.e.,emitter), as shown in FIG. 1 , can be disposed in the distal end 125 ofthe electrode 104 so that an emission surface is exposed. The insert 142can be made of hafnium or other materials that possess suitable physicalcharacteristics, including corrosion resistance and a high thermionicemissivity. Forging, impact extrusion, or cold forming can be used toinitially form the electrode 104 prior to finish machining thecomponent.

The nozzle 108 can be spaced from the distal end 125 of the electrode104 and define, in relation to the electrode 104, a plasma chamber 140.FIG. 3 is an isometric view of the nozzle 108, according to anillustrative embodiment of the invention. The nozzle 108 includes acentrally-located exit orifice 144 for introducing a plasma arc, such asan ionized gas jet, to a workpiece (not shown) to be cut.

In some embodiments, the swirl ring 102 has a set of radially spaced gasflow openings 136 configured to impart a tangential velocity componentto a gas flow for the plasma arc torch, causing the gas flow to swirl.This swirl creates a vortex that constricts the arc and stabilizes theposition of the arc on the insert 142. In some embodiments, the sealingdevice 150, such as an o-ring, can be located on an external surface ofthe swirl ring 102 at its proximal end 112 to engage an internal surfaceof the plasma arc torch body (not shown) when the cartridge 100 isinstalled into the plasma arc torch body. The sealing device 150 isconfigured to provide a leak-proof seal of fluids (e.g., gases) betweenthe cartridge 100 and the plasma arc torch body at that location.

FIGS. 4 a and 4 b are isometric and profile views of the swirl ring 102of the cartridge 100 of FIG. 1 , respectively, according to anillustrative embodiment of the invention. As shown, the swirl ring 102can be defined by a substantially hollow, elongated body 103 having thedistal end 110 and the proximal end 112 along the longitudinal axis A.The distal end 110 of the swirl ring 102 is characterized as the endthat is closest to a workpiece when operating the cartridge 100 withinthe plasma arc torch, and the proximal end 112 is the opposite of thedistal end 110 along the longitudinal axis A. In some embodiments, thehollow body 103 of the swirl ring 102 is dimensioned to receive theelectrode 104 and substantially extend over the length of the electrode104 along the longitudinal axis A. The inner wall of the swirl ring 102can thus radially align the electrode 104 by limiting a radial movementof the electrode 104. An interface 118 can be formed between the distalend 110 of the swirl ring 102 and the nozzle 108 to join the twoconsumable components together as a part of the cartridge 100. Anotherinterface 120 can be formed between the proximal end 112 of the swirlring 102 and the end cap 106 to join the two consumable componentstogether as a part of the cartridge 100. In general, the interface 118and/or the interface 120 form a chamber in which the electrode 104 ispermanently disposed and aligned (longitudinally and radially) relativeto the nozzle 108 and the end cap 106.

In some embodiments, the one or more gas flow openings 136 of the swirlring 102 are disposed about the distal end 110 of its elongated body103, such as around a circumference of its distal end 110. In someembodiments, the one or more gas flow openings 136 are molded. Each gasflow opening 136 can extend from an interior surface to an exteriorsurface of the elongated body 103 and is oriented to impart a swirlingmotion relative to the axis A to the gas (e.g., air) flowingtherethrough. Each gas flow opening 136 can be circular or non-circular(e.g., rectangular, squared and/or square-cornered) in geometry. In someembodiments, the gas flow openings 136 have substantially uniformdimensions. In some embodiments, as shown in FIGS. 4 a and 4 b , the gasflow openings 136 are at least partially defined by slots 202 at thedistal end 110 of the elongated body 103 of the swirl ring 102. Thesegas flow slots 202 are formed by a plurality of extensions 204 spacedapart at regular or non-regular intervals around the circumference ofthe distal end 110, where each slot 202 is situated between a pair ofthe extensions 204. Upon the swirl ring 102 being securely affixed tothe nozzle 108, the slots 202 are closed off by the proximal end of thenozzle 108 to create bounded holes. Hence, each gas flow opening 136 canbe a two-piece composite opening cooperatively defined by the nozzle 108and the swirl ring 102.

In some embodiments, to form the interface 118 between the swirl ring102 and the nozzle 108, the swirl ring 102 can include a nozzleretention surface 216 (e.g., interior and/or exterior surface) of theelongated body 103 for securely attaching the nozzle 108 at its distalend 110. In one example, as illustrated in FIGS. 4 a and b , the nozzleretention surface 216 can be a feature, such as one or more grooveslocated on the external surface of the elongated body 103, such as onthe extensions 204. The nozzle retention surface 216 can capture thenozzle 108 through one of snap fit, crimping, or threading to form theinterface 118. In a crimping example, a portion of the nozzle 108 can becrimped against and into the groove 216 to securely affix the nozzle 108to the swirl ring 102. Alternatively, a similar retention surface can bedisposed on the nozzle 108 to retain the swirl ring 102 thereto. Othermanufacturing and assembly options are available and viable to connectthe two components. For example, the nozzle 108 can be over-molded ontothe swirl ring 102 to form the interface 118.

FIGS. 5 a and b are isometric and sectional views of another swirl ring702 compatible with the cartridge 100 of FIG. 1 , respectively. Asshown, the swirl ring 702 is substantially similar to the swirl ring 102except that the nozzle retention surface 716 of the swirl ring 702comprises a sloped surface at a tapered angle relative to thelongitudinal axis A. The sloped surface 716 can beis adapted to capturethe nozzle 108 through one of snap fit, crimping, or threading to formthe interface 118 of FIG. 1 .

In some embodiments, as shown in FIGS. 4 a and b , to form the interface120 between the swirl ring 102 and the end cap 106, the swirl ring caninclude a cap retention feature 230 located on a surface (e.g., interiorand/or exterior surface) of the elongated body 103 for securelyretaining the end cap 106 at its proximal end 112. The cap retentionfeature 230 can be one or more grooves that capture the end cap 106through one of snap fit, crimping, or threading to form the interface120. For example, a portion of the end cap 106 can be crimped into thegroove(s) 230 to securely affix the end cap 106 to the swirl ring 102.In some embodiments, as shown in FIGS. 1 and 4 b, a lip portion 232 ofthe proximal end 112 of the swirl ring 102 is inserted inside of the endcap 106 after the two components are coupled together. Alternatively, asimilar retention feature can be disposed about the end cap 106 to jointhe swirl ring 102. Other manufacturing and assembly options areavailable and viable to connect the two components. For example, the endcap 106 can be over-molded onto the swirl ring 102 to form the interface120. A similar cap retention feature 730 can be located on a surface ofthe swirl ring 702 of FIGS. 5 a and b and provide substantially the samefunction as the cap retention feature 230.

In general, each of the retention surfaces/elements 216, 230 of FIGS. 4a and b simplifies alignment of the parts in the cartridge 100 incomparison to an operator having to perform alignment of individualcomponents without any structural guidance. In some embodiments, thelocking of the swirl ring 102 to the nozzle 108 at the interface 118 viathe retention element 216 aligns the two components relative to eachother and further retains the electrode 104 in the chamber formed by thelocking of the swirl ring 102 and the nozzle 108. The inner wall of theswirl ring 102 can radially align the electrode 104 such that there is arelatively small gap between the inner wall of the swirl ring 102 andthe radial fins 114 of the electrode 104, thereby limiting a radialmotion of the electrode 104. This thus establishes a radial centering ofthe nozzle exit orifice 144 with respect to the distal end 125 of theelectrode 104 within the chamber, such as within a tolerance of about0.005 inches. In some embodiments, the locking of the swirl ring 102 tothe end cap 106 at the interface 120 via the retention element 230aligns the two components relative to each other and furtherlongitudinally aligns the electrode 104 in the chamber. For example,after the swirl ring 102 and the end cap 106 are joined, the depth ofthe depressed center 304 of the end cap 106 controls how far back theelectrode 104 can move longitudinally toward the proximal end 124 inrelation to the nozzle 108 during a transferred arc mode (e.g., when agas flow is used to bias the electrode 104 into contact with the end cap106 ), such as within a blow-back distance of 0.02 to 0.12 inches. Thelocking of the swirl ring 102 to the end cap 106 at the interface 120via the retention element 230 also secures the resilient element 122within the cartridge 100 while accurately positioning the resilientelement 122 relative to the proximal end 124 of the electrode 104. Inaddition, the joining of the nozzle 108 to the swirl ring 102 helps todefine the longitudinal motion of the electrode 104 to within theblow-back distance between the distal end 125 of the electrode 104 andthe nozzle exit orifice 144 during the transferred arc operation. Suchrestraint on the longitudinal motion of the electrode 104 promotesaccuracy and repeatability of plasma arc initiation in torch operations.Similarly, each of the retention surfaces/elements 716, 730 of FIGS. 5 aand b simplifies alignment of the parts in the cartridge 100 uponassembly of the swirl ring 702 into the cartridge 100.

In some embodiments, the gas flow openings 136 of the swirl ring 102 aresuitably shaped and dimensioned to enhance swirling of a gas flowtherethrough. FIG. 6 is a sectional view of the swirl ring 102 of thecartridge 100 of FIG. 1 with the electrode 104 radially aligned withinthe swirl ring 102 and illustrating an exemplary gas flow opening 136.

As shown, the swirl ring 102 and the electrode 104 have a shared center602. Width W represents the curved axial width of each gas flow opening136 (only one gas flow opening is shown). Length R represents theaverage distance (radius) between the center of the electrode 104 andthe radius of the annular space between the exterior of the electrodebody and the inner wall of the swirl ring 102, as measured from theshared center 602. In some embodiments, the W/R ratio is less than about0.5. This value allows a gas flow entering a gas flow opening 136 toimpinge somewhat perpendicularly on surface of the electrode 104,increasing gas turbulence and enhancing electrode cooling. In contrast,a traditional gas flow opening design has a W/R ratio of about 1.0,which causes a gas to impinge at most tangentially relative to a surfaceof the electrode 104. The substantial perpendicular impingement (asopposed to the tangential impingement) generates more flow distribution,more uniform gas flow swirling, and better cooling of the electrode 104.In some embodiments, the life of the electrode 104 is extended by 25%when the W/R ratio is less than about 0.5. This design ratio isapplicable to gas flow openings 136 represented by slots 202 molded atthe distal end 110 of the swirl ring 102 or by enclosed holes (notshown) formed, molded, or drilled into the distal end 110.

In some embodiments, only one row of gas flow openings 136 is disposedaround the distal end 110 of the swirl ring 102. For example, one row oftwelve gas flow openings 136 can be disposed symmetrically about theswirl ring 102. In contrast, traditional swirl ring designs have two ormore rows (layers) of gas flow openings, with some traditional swirlrings having eighteen openings per row. Due to the reduced number of gasflow openings 136 in the present design, the width W of individual gasflow openings 136 is increased to generate the same gas flow swirl forceand maintain the same overall cross-sectional area of the gas flowopenings 136 combined in comparison to the traditional designs. Inaddition, for each gas flow opening 136, the offset O between theopening 604 in the inner wall of the swirl ring 102 and the opening 606on the outer wall of the swirl ring 102 is reduced (e.g., to about lessthan or equal to about 0.040 inches) whereas such an offset associatedwith a gas flow opening of a traditional swirl ring design is larger(e.g., about 0.12 inches) In general, reducing the number of gas flowopenings 136, coupled with locating the openings 136 on a single row,simplifies manufacturing cycle time, reduces material cost, and is morecompatible with an injection molding approach for manufacturing theswirl ring 102. The gas flow opening design described with respect tothe swirl ring 102 can also be applied to the swirl ring 702 of FIGS. 5a and b.

In some embodiments, the swirl ring 102 or 702 is manufactured throughinjection molding of one or more high-temperature thermoplasticmaterials comprising a polymer formed of ether and ketone molecules(e.g., ether ketone based compounds), such as polyetheretherketone(PEEK), polyaryletherketone (PAKE), polyetherketoneketone (PEKK),polyetherketoneetherketone-ketone (PEKEKK) and variants thereof.Exemplary thermoplastic materials also include polyamide-imide (PAI),polyetherimide (PEI), and/or polytetrafluoroethylene (PTFE). In someembodiments, properties associated with suitable thermoplastic materialsfor the invention have a glass transition temperature (Tg) of greaterthan about 320 Fahrenheit, a coefficient of linear thermal expansion(CLTE) of less than about 22 micro-inch/inch-Fahrenheit below Tg, a CLTEof less than about 55 micro-inch/inch-Fahrenheit above Tg, a meltingpoint of greater than about 720 Fahrenheit, and/or a dielectric strengthof greater than about 480 kilo-volt/inch. The use of thermoplastics tomanufacture swirl rings reduces cartridge cost in comparison to, forexample, Vespel™, Torlon, Celazole or Phenolic compounds or otherthermal-set plastics, which are materials currently used to manufactureswirl rings, but are comparatively more expensive to obtain anddifficult to use. However, it is known that thermoplastics haveoperating temperatures that are lower than thermos-set Vespel™, whichcan potentially impact the integrity of swirl rings and electrode lifein general. To resolve the high temperature performance issues, theswirl ring 102 or 702 can be made from thermoplastic resins having oneor more fortifying additives to provide the desired thermal resistanceand/or thermal conductivity, thus enabling effective use ofthermoplastic material(s) in cartridges and/or swirl rings. Exemplaryfortifying additives include glass fibers, minerals, boron nitride (BN),Cubic BN and/or Vespel™ particles. As an example, the materialpolymide/polyetheretherketone (PI/PEEK), a heat resistant material thatcan include about 50% recycled Vespel™ particles, can be used tomanufacture the swirl ring 102 or 702. In addition, the swirl ring 102or 702 is positioned in such a location in the cartridge 100 that itavoids exposure to the highest operating temperatures during torchoperation. Thus, in practice, using a thermoplastic material tomanufacture the swirl ring 102 is unlikely to affect the integrity ofthe swirl ring 102 or 702. Furthermore, when the electrode 104experiences an end-of-life event, which is also the end of life of thecartridge 100, the plastic material melts, which does not affect thecutting operation during the consumable life. In contrast, knownthermal-set based swirl rings, which are reused repeatedly with varioussets of electrodes and nozzles, commonly have lifecycles of 20 to 30times that of electrodes and nozzles. These lifecycles placerequirements and demands on the swirl rings, which can lead to overdesign and also inconsistent performance as the swirl rings canthermally warp (e.g., expand and/or shrink) over their lifecycles,providing different fits, interfaces, and performance based on lifecycleposition.

In some embodiments, the elongated body 103 of the swirl ring 102 isformed using an injection molding technique (e.g., thermoplasticinjection molding). In some embodiments, if the gas flow openings 136include slots 202 defined by the distal end 110 of the swirl ring 102,the slots 202 can be formed at the same time as the elongated body 103via the same thermoplastic injection molding process. In general, thegas flow slots 202, in contrast to drilled holes in accordance withtraditional designs for creating gas flow passageways, are morecompatible with the injection molding technique for forming the swirlring 102. Thus, molding the gas flow slots 202 into the swirl ring body103 eliminates the additional step of drilling holes into the body 103.Using gas flow slots 202 instead of drilled holes in a swirl ring designalso reduces material cost and the cost of long cycle time associatedwith drilling operations. The nozzle retention feature 216 and/or thecap retention feature 230 can also be formed at the same time as theelongated body 103 via the same thermoplastic injection molding process.Therefore, most, if not all, of the swirl ring 102 can be manufacturedusing a cost-effective single injection molding process. Overall, amolded thermoplastic process for forming the swirl ring 102 provides afaster and cheaper manufacturing approach in comparison to thetraditional processes. Processes and materials for manufacturing theswirl ring 102 of FIGS. 4 a and b can also be used to manufacture theswirl ring 702 of FIGS. 5 a and b.

FIGS. 7 a and b are isometric and sectional views of the end cap 106 ofthe cartridge 100 of FIG. 1 , respectively, according to an illustrativeembodiment of the invention. The end cap 106 provides at least one ofthe following functions: (i) securely engaging the swirl ring 102 or 702at its proximal end 112 to form the interface 120, thereby aligning theelectrode 104; (ii) providing a holder for the resilient element 122;and (iii) passing an electrical current to the electrode 104 in ablow-back contact-start configuration. As illustrated, the end cap 106has a substantially hollow body 300 defining a proximal end 320 and adistal end 322. The hollow body 300 includes a circular tunnel portion302 and a depressed center 304 extending away from the proximal end 320of the end cap 106. In some embodiments, the body 300 of the end cap 306has a substantially uniform thickness, thereby promoting efficient anduniform current passage and assisting with the establishment of preciseconsumables alignment. Uniform thickness of the end cap 106, coupledwith a stamp manufacturing technique, also simplifies manufacturing andminimizes manufacturing cycle time, consumable weight, and materialusage.

In some embodiments, an interior surface 308 of the circular tunnelportion 302 at the proximal end 320 defines a biasing surface forphysically contacting and electrically communicating with the resilientelement 122. The resilient element 122 can bias against the proximal end124 of the electrode 104 so as to move the electrode 104 away from theend cap 106. That is, the resilient element 122 is situated between andphysically contacts the biasing surface 308 of the end cap 106 and theproximal end 124 of the electrode 104 such that the resilient element122 imparts a separation force between the electrode 104 and the biasingsurface 308.

In some embodiments, an interior surface 310 of the depressed center 304of the end cap 106 at the distal end 322 defines a contact surface thatis configured for physical contact and electrical communication with acorresponding contact surface 128 of the electrode 104 at its proximalend 124. During the transferred arc mode, the contact surface 310 of theend cap 106 is in an abutting relationship with the correspondingcontact surface 128 of the electrode 104. However, during the initiationof a pilot arc in the pilot arc mode, the contact surface 310 is in aspaced relationship with the corresponding contact surface 128 that isdefined by an absence of contact between the two surfaces.

The resilient element 122 is generally maintained inside of thecartridge 100 between the end cap 106 and the electrode 104. In someembodiments, the resilient element 122 is secured to either the end cap106 or the electrode 104. In other embodiments, the resilient element122 is secured to both the electrode 104 and the end cap 106. Forexample, the resilient element 122 can be secured by welding, soldering,bonding, fastening, a diametral interference fit or another type offriction fit to the end cap 106 and/or the electrode 104. In someembodiments, the substantially hollow body 300 of the end cap 106 isconfigured to house the resilient element 122 between its biasingsurface 308 and the proximal end 124 of the electrode 104. For example,the circular tunnel portion 302 of the end cap 106 can function as aholder of the resilient element 122. Specifically, the resilient element122 can be held in place by the biasing surface 308, an inner interiorsurface 312 and an outer interior surface 314 of the tunnel portion 302,where the diameter of the inner interior surface 312 with respect to thelongitudinal Axis A is slightly smaller than the inner diameter of theresilient element 122, and the diameter of the outer interior surface314 with respect to the longitudinal Axis A is slightly larger than theouter diameter of the resilient element 122.

In some embodiments, radial movement of the resilient element 122 isfurther restrained by the proximal end 112 of the swirl ring 102 or 702after the swirl ring 102 or 702 is affixed to the end cap 106. As shownin FIG. 1 , after the end cap 106 is coupled to the swirl ring 102(e.g., by being crimped into the cap engagement groove 230), the lipportion 232 of the swirl ring 102 can extend into the interior of thecircular tunnel portion 302 of the end cap 106. Therefore, the lipportion 232 can further restrain and guide the positioning of theresilient element 122 inside of the end cap 106.

In some embodiments, the end cap 106 is configured to be in electricalcommunication with a power supply (not shown) when the cartridge 100 isinstalled within a torch. This enables a flow of current from the powersupply to the electrode 104 via the resilient element 122 and/or thecontact surface 310, depending on the mode of torch operation. In someembodiments, at least one vent hole 316 (or gas exit orifice) isdisposed in the end cap 106, extending from an interior surface to anexterior surface of the body 300 to cool the cartridge 100. For example,a vent hole 316 can be located on the circular portion 302.Alternatively, vent hole(s) 316 are absent from the end cap 106.

In one exemplary operation, during pilot arc initiation, the powersupply provides a pilot arc current to the end cap 106 and the pilot arccurrent is passed to the electrode 104 through the resilient element 122that biases the electrode 104 against nozzle 108. As the resilientelement 122 urges the electrode 104 into abutting relation with thenozzle 108, there is an absence of physical contact and electricalcommunication between the contact surface 310 of the end cap 106 and thecorresponding contact surface 128 of the electrode 104. The resilientelement 122 can be configured to pass substantially all of the pilot arccurrent from the end cap 106 to the electrode 104.

During pilot arc initiation, a gas is introduced into the plasma chamber140 between the electrode 104 and the nozzle 108. Gas pressure can buildwithin the plasma chamber 140 until the pressure is sufficient toovercome the separation force exerted by the resilient element 122. Atthat point, the gas pressure moves the electrode 104 toward the end cap106 and away from the nozzle 108 along the longitudinally axis A (whilecompressing the resilient element 122) until the corresponding contactsurface 128 of the electrode 104 comes into physical contact with thecontact surface 310 of the end cap 106. As the electrode 104 is movedaway from the nozzle 108 by gas pressure, an arc is generated orinitiated in the plasma chamber 140 to form a plasma arc or jet that canbe transferred to a workpiece (not shown).

During transferred arc mode, the corresponding contact surface 128 ofthe electrode 104 engages in substantially planar physical contact withthe contact surface 310 of the end cap 106 to establish electricalcommunication (e.g., electrical current passes between the end cap 106and the electrode 104 at the interface of the contact surface 310 andthe corresponding surface 128). When the contact surface 310 of the endcap 106 abuts the corresponding surface 128 of the electrode 104, acurrent path is established such that at least a portion of a currentpasses directly between the two components. When the arc has beentransferred to the workpiece, a cutting current is supplied to the torch(e.g., during transferred arc mode). The cutting current can be passedfrom the end cap 106 to the electrode 104 during transferred arcoperation via (1) the resilient element 122 and/or (2) the interfacebetween the contact surfaces 310, 128. In some embodiments, the currentpath directly between the end cap 106 and the electrode 104 has lowerresistance and/or higher conductance than the current path from the endcap 106 through the resilient element 122 to the electrode 104. Hence,substantially all of the electrical current for sustaining a plasma arc(in transferred arc mode) can be passed directly between the contactsurfaces 128, 310.

In some embodiments, the resilient element 122 is formed from a materialthat facilitates both carrying an electrical current and dissipatingthermal heat associated with the current to prevent the resilientelement 122 from melting. For example, the material of the resilientelement 122 can be selected based on the current rating of the material.In some embodiments, the resilient element 122 comprises a helicalcompression spring, wire, or metal strip. For example, different typesof resilient element 122 configurations are described in U.S. Ser. No.13/344,860, assigned to Hypertherm, Inc., of Hanover, N.H., the contentsof which are hereby incorporated herein by reference in their entirety.

In some embodiments, the end cap 106 is fabricated from an electricallyconductive material, such as copper, copper alloy, brass, or othermaterials suitable for passing current both during pilot arc operationand transferred arc operation. The end cap 106 can be formed using astamping approach from a material blank.

In another aspect, the cartridge 100 can additional include a shield.FIG. 8 shows an exemplary shield 600 compatible with the cartridge 100of FIG. 1 , according to an illustrative embodiment of the invention.The shield 600 can be made from a conductive material, such as copper orsilver. The shield 600 can be affixed to the nozzle 108 via one ofcrimping, threading and snap-fit. In some embodiments, a flow passageway(not shown) is disposed in the nozzle 108 to allow a gas (e.g., a shieldgas) to flow through/by the nozzle 108 to the shield 600.

FIG. 9 is an exploded view of the cartridge 100 of FIG. 1 , according toan illustrative embodiment of the invention. FIG. 9 shows the nozzle108, the electrode 104, the swirl ring 102, the resilient element 122,the sealing device 150, and the end cap 106 in an unassembled statebefore forming the cartridge 100. In some embodiments, the insert 142 isalso a part of the cartridge 100. During assembly, the electrode 104 ishoused in the chamber formed by the coupling of the nozzle 108 to thedistal end 110 of the swirl ring 102. The nozzle 108 can be securelyaffixed to the outer wall of the swirl ring 102 through the retentionelement 216 (e.g., a groove disposed on the swirl ring 102 against whichthe nozzle 108 is crimped or a thread to which the nozzle 108 isthreaded). This interconnection secures the electrode 104 within thecartridge 100 while the inner wall of the swirl ring axially aligns theelectrode 104 about the longitudinal axis A with respect to the nozzle108 such that the electrode 104 is limited in its axial motion. Theresilient element 122 is inserted into the swirl ring 102 from itsproximal end 112 until it contacts the proximal end 124 of the electrode104 within the swirl ring 102. The end cap 106 is then securely affixedto the proximal end 112 of the swirl ring 102 while substantiallyconfining the resilient element 122 in the circular portion 304 of theend cap 106 and axially aligning the resilient element relative to theend cap 106. The end cap 106 can be connected to the swirl ring 102through the retention element 230 (e.g., a groove disposed on the swirlring 102 against which the end cap 106 is crimped or a thread to whichthe end cap 106 is threaded). This interconnection enables the biasingsurface 308 of the end cap 106 to bias the resilient element 122 againstthe proximal end of the electrode 104, thereby urging it into anabutting position with the nozzle 108. This interconnection alsolongitudinally aligns the electrode 104 with respect to the end cap 106such that during the transferred arc mode, the electrode 104 is onlyable to retract from the nozzle 108 far enough until it abuts thecontact surface 310 of the depressed portion 304 of the end cap 106.Furthermore, the sealing device 150 can be disposed around an exteriorsurface of the proximal end 112 of the swirl ring 102 either before orafter the end cap 106 is affixed to the swirl ring 102. In someembodiments, the swirl ring 702 of FIGS. 5 a and b are used in thecartridge 100 in place of the swirl ring 102.

In some embodiments, a method is provided to assemble the cartridge 100of FIG. 1 . First, a thermoplastic material is molded to form the swirlring 102 or 702. Various features of the swirl ring 102 or 702 can becreated during the same molding process, such as the gas flow openings136 and/or the nozzle retention surface 216 molded at the distal end 110of the swirl ring 102. Similar features can be molded onto the swirlring 702. During assembly, the electrode 104 can be disposed inside ofthe hollow body of the swirl ring 102 or 702. The inside wall of theswirl ring 102 or 702 can radially align the electrode 104. Theelectrode can be retained within the swirl ring 102 or 702 by fixedlysecuring the nozzle 108 to the distal end 110 of the swirl ring 102 or702 via the nozzle retention surface 216 or 716, respectively. Forexample, the fixedly securing can be achieved through one of crimping,threading or snap-fitting with respect to the nozzle retention surface216 or 716. Upon affixing the nozzle 108 to the swirl ring 102 or 702, aradial centering of the nozzle exit orifice 144 with respect to thedistal end 125 of the electrode 104 is established. The electrode 104can be longitudinally aligned relative to the nozzle 108 by fixedlysecuring an end cap 106 to the proximal end 112 of the swirl ring 102 or702 via the cap retention element 230 or 730, respectively, therebyestablishing the longitudinal alignment during a transferred arcoperation of the cartridge 100 when a gas flow is used to bias theelectrode 104 into contact with the end cap 106. Specifically, duringthe transferred arc mode, the longitudinal alignment includesrestraining a longitudinal motion of the electrode 104 to within ablow-back distance defined by the distal end 125 of the electrode 104and the exit orifice 144 of the nozzle 108. In some embodiments, theresilient element 122 is inserted into the end cap 106 and housed in thetunnel portion 302 of the end cap 106 prior to affixing the end cap tothe swirl ring 102 or 702. In some embodiments, the sealing device 150,such as in the form of an o-ring, can be located on an external surfaceof the swirl ring 102 or 702 at its proximal end 112 to engage aninternal surface of the plasma arc torch body (not shown) when thecartridge 100 is installed into the plasma arc torch body.

Test results have shown that the cartridge design 100 of FIG. 1 ,operating at a current of 105 amps, can have the same or betterperformance than that of individual consumables (e.g., a nozzle,electrode, and swirl ring) assembled into a PMX 105 Amp plasma arc torch(operated at 105 amps), and at a lower manufacturing cost. Table 1 showsa comparison of performance and cost between the cartridge 100 and theindividual consumables for a PMX 105 Amp plasma arc torch.

Cartridge 100 PMX 105 Amp Torch Anode life at 105A (hours) 2.5 2.2 Maxcut speed at ½″ mild 95 95 steel (in per minute)The cost of the cartridge 100, which represents the combined cost of aswirl ring, electrode and nozzle (i.e., without an end cap), is lowerthan the total cost of the individual consumables in a PMX 105 Amptorch, which includes the cost of just a nozzle and an electrode (i.e.,when a swirl ring is not even considered). In term of performance, atorch having the cartridge 100 installed therein has comparable maximumcut speed as compared to a PMX 105 Amp torch that contains individualconsumable components. Performance of a torch containing the cartridge100 is also better in terms of anode life.

In addition to the benefits described above, there are many othersbenefits associated with using the cartridge 100 in a plasma arc torch.First, such a design promotes ease of use through quick changecapabilities, short setup time and ease of consumable selection for anend user. It also provides consistent cut performance because a suite ofconsumables are changed at once when the cartridge is changed, where thecartridge promotes easy component alignment, thus accuracy andrepeatability of torch operation. In contrast, variation in performanceis introduced when components are changed individually at differenttimes. For example, there is more room to make an error when an operatorhas to align and orient individual torch components relative to eachother. In another example, long term re-use of the same component (e.g.,a swirl ring) can cause dimensional alteration after each blow-out,thereby altering the performance quality even if all other componentsare changed regularly. In addition, since the manufacturing and/orinstallation cost of a cartridge is lower than the combined cost of aset of consumables, there is a lower cost associated with per cartridgechange than per change of a set of consumables. Furthermore, differentcartridges can be designed to optimize torch operation with respect todifferent applications, such as marking, cutting, maintaining long life,etc.

In some embodiments, the cartridge 100 is single use, meaning thatdisassembly and replacement of individual components at the end of thelife of the cartridge is not practical or cost effective. The entirecartridge 100 is discarded and/or disposed (e.g., recycled), withoutreplacing individual particular parts. If the cartridge 100 is recycled,in addition to recovering the copper, a benefit of constructing theswirl ring 102 of a thermoplastic material is that the material can bereheated, reshaped, and frozen repeatedly, thus making it easilyrecyclable. In contrast, Vespel™ and other thermal-set materials lackthese characteristics that promote recyclability.

It should be understood that various aspects and embodiments of theinvention can be combined in various ways. Based on the teachings ofthis specification, a person of ordinary skill in the art can readilydetermine how to combine these various embodiments. Modifications mayalso occur to those skilled in the art upon reading the specification.

What is claimed is:
 1. A swirl ring for an air-cooled plasma arc torch,the swirl ring comprising: an elongated body comprising a substantiallyhollow portion, the elongated body having a distal end and a proximalend and configured to receive an electrode within the hollow portion; aplurality of gas flow openings each extending from an interior surfaceto an exterior surface of the elongated body, the gas flow openingsdisposed about the distal end of the elongated body and configured toimpart a swirl to a plasma gas flow of the plasma arc torch, wherein theplurality of gas flow openings include gas flow slots defined by aplurality of extensions located at spaced intervals around acircumference of the distal end of the elongated body of the swirl ring,each gas flow slot situated between a pair of the extensions and extendsfrom the interior surface to the exterior surface of the elongated bodyto impart the swirl to the plasma gas flowing between the interior andexterior surfaces; and a nozzle retention surface on the body forretaining a nozzle at the distal end of the elongated body.
 2. The swirlring of claim 1, wherein the nozzle retention surface includes a nozzleretention feature located on an external surface of the extensions. 3.The swirl ring of claim 2, wherein the nozzle retention featurecomprises a groove configured to receive a portion of the nozzle viacrimping.
 4. The swirl ring of claim 1, wherein the nozzle retentionsurface comprises a sloped surface configured to receive a portion ofthe nozzle via crimping.
 5. The swirl ring of claim 1, wherein thedistal end of the elongated body of the swirl ring and the nozzlecooperatively define the plurality of gas flow openings.
 6. The swirlring of claim 1, wherein the swirl ring is configured to engage thenozzle via one of snap fit or threading.
 7. The swirl ring of claim 1,wherein the swirl ring is configured to engage the nozzle via crimping.8. The swirl ring of claim 1, wherein the elongated body is formed in aninjection molding process.
 9. The swirl ring of claim 8, wherein atleast one of the nozzle retention feature or the plurality of gas flowopenings are molded onto the elongated body in the same injectionmolding process.
 10. The swirl ring of claim 1, wherein the elongatedbody is formed from a thermoplastic material.
 11. The swirl ring ofclaim 10, wherein the thermoplastic material comprises a polymer formedof ether and ketone molecules.
 12. The swirl ring of claim 11, whereinthe thermoplastic material further comprises one or more additives. 13.The swirl ring of claim 11, wherein the thermoplastic material has oneor more properties comprising (i) a glass transition temperature (Tg) ofgreater than about 320 Fahrenheit (F), (ii) a coefficient of linearthermal expansion (CLTE) of less than about 22micro-inch/inch-Fahrenheit (micro.in/in.F) below Tg, (iii) a CLTE ofless than about 55 micro.in/in.F above Tg, (iv) a melting point ofgreater than about 720 Fahrenheit, and (v) a dielectric strength ofgreater than about 480 kilo-volt/inch.
 14. The swirl ring of claim 1,further comprises a cap retention element located on the elongated bodyfor retaining a cap at the proximal end of the elongated body, the capsubstantially encloses the proximal end.
 15. The swirl ring of claim 14,wherein the cap retention element comprises a groove configured tosecure the cap by at least one of crimping, threading, or snap fit. 16.The swirl ring of claim 14, wherein the elongated body of the swirlring, in cooperation with the cap, is adapted to longitudinally alignthe electrode to retrain a longitudinal motion of the electrode.
 17. Theswirl ring of claim 1, wherein a ratio of an axial width (W) of each gasflow opening to an average radius (R) between a radius of the electrodeand a radius of an inner wall of the swirl ring is less than about 0.5.18. The swirl ring of claim 1, wherein the plurality of gas flowopenings are disposed in a single layer about the distal end of theelongated body.
 19. The swirl ring of claim 18, wherein each gas flowopening has an offset of 0.040 inches between an opening in an innerwall of the swirl ring and an opening on an outer wall of the swirlring.
 20. The swirl ring of claim 1, wherein the elongated body of theswirl ring, in cooperation with the nozzle, is adapted to radially alignthe electrode to limit a radial motion of the electrode.
 21. A methodfor assembling a plurality of components in a cartridge that includesthe swirl ring of claim 1, the method comprising: molding athermoplastic material to form the swirl ring; disposing an electrodeinside of the hollow body of the swirl ring; retaining a nozzle at thedistal end of the swirl ring to capture the electrode within thecartridge; and securing an end cap to the proximal end of the swirl ringto longitudinally align the electrode relative to the nozzle, therebyestablishing the longitudinal alignment during a transferred arcoperation of the cartridge when a gas flow is used to bias the electrodeinto contact with the end cap.
 22. The method claim 21, furthercomprising radially aligning the electrode by restraining a radialmotion of the electrode within the hollow body of the swirl ring. 23.The method of claim 21, wherein the longitudinal alignment comprisesrestraining a longitudinal motion of the electrode to within a blow-backdistance defined by a distal end of the electrode and an exit orifice ofthe nozzle during the transferred arc operation.
 24. The method claim21, wherein retaining the nozzle to the distal end of the swirl ringcomprises crimping a portion of the nozzle into the nozzle retentionsurface on the distal end of the swirl ring.
 25. The method of claim 21,wherein molding a thermoplastic material to form the swirl ringcomprises: forming the hollow body from the thermoplastic material; andforming the plurality of gas flow openings.
 26. The method of claim 25,further comprising forming the nozzle retention surface on the hollowbody using the thermoplastic material.
 27. The method of claim 26,further comprising forming the hollow body, the plurality of gas flowopenings, and the nozzle retention surface of the swirl ring from asingle injection molding process.
 28. The method of claim 25, whereinforming the plurality of gas flow openings comprises forming the slotsdefined by the plurality of extensions disposed about the distal end.29. The method of claim 21, wherein the thermoplastic material comprisesa polymer formed of ether and ketone molecules.
 30. The method of claim29, wherein the thermoplastic material comprises a polymer formed ofether and ketone molecules.
 31. The method of claim 21, wherein the endcap is formed from an electrically conductive material.
 32. The methodof claim 21, further comprising positioning a resilient element betweenthe end cap and the electrode.
 33. The method of claim 32, wherein theresilient element is configured to pass substantially all of a pilot arccurrent from a power supply to the electrode.
 34. A method for retaininga nozzle to the swirl ring of claim 1 in a plasma arc torch, the methodcomprising: providing the swirl ring of claim 1; providing a nozzle witha proximal end and a distal end; attaching the proximal end of thenozzle to the nozzle retention surface of the swirl ring to secure andalign the nozzle relative to the swirl ring; and forming the pluralityof gas flow openings by closing the gas flow slots of the swirl ring bythe proximal end of the nozzle upon attaching the nozzle to the swirlring, wherein the gas flow openings are configured to impart a swirl toa plasma gas flow of the plasma arc torch.
 35. The method of claim 24,wherein the nozzle retention surface comprises one or more grooveslocated on an external surface of the elongated body.
 36. The method ofclaim 35, wherein the one or more grooves are located on the pluralityof extensions.
 37. The method of claim 34, wherein the nozzle retentionsurface is configured to attach the nozzle through one of snap fit,crimping or threading.
 38. The method of claim 37, further comprisingretaining an electrode inside of a chamber formed upon attaching thenozzle to the swirl ring, the nozzle adapted to restrain a longitudinalmovement of the electrode.
 39. The method of claim 34, furthercomprising radially centering a nozzle exit orifice of the nozzle withrespect to the electrode upon attaching the nozzle to the swirl ring.